JP2017019394A - Control apparatus for power transmission device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a control apparatus for a power transmission device, the apparatus capable of driving an engine in a state of charging being limited, thus making it possible to obtain necessary and sufficient drive power.SOLUTION: In a control apparatus for a power transmission device including a differential mechanism 22 that is enabled to divide power output from an engine 20 toward a drive wheel 31 and a generator 23, to drive a motor with the power generated by the generator 23 to output torque of a motor 32 toward the drive wheel 31, and to charge a power storage device 41 with at least a portion of the power generated by the generator 23, the motor 32 is disposed at a position out of a transmission path L that transmits the power of the engine 20 to the drive wheel 31 via the differential mechanism 22; a hydraulic coupling 33 is disposed between the motor 32 and the transmission path L; and in a case where charging of the power storage device 41 with the power generated by the generator 23 is limited, the motor 32 is driven while the hydraulic coupling 33 is put to a differential motion, thus a loss is generated.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a control device for a power transmission device including an engine, a generator, and an electric motor.

  Patent Document 1 describes a power train for a hybrid vehicle including a hybrid drive device and a four-speed automatic transmission. The hybrid drive device connects an engine and a generator to a differential mechanism, controls the engine speed by an electric motor, amplifies the engine torque and outputs it from the differential mechanism, and uses the electric power generated by the generator to drive the electric motor. And the output torque of the electric motor is added to the torque output from the differential mechanism. The generator and the motor are electrically connected to the power storage device, and the power storage device is configured to charge surplus power when the amount of power generated by the generator is greater than the amount of power consumed by the motor. Has been. Moreover, in the apparatus described in Patent Document 1, a surplus energy is consumed by slipping a clutch provided on the output side of the electric motor.

JP 2014-113895 A

  If surplus energy is consumed by slipping the clutch, the restriction on the amount of power generated by the generator will be reduced by the amount of energy consumed, so the engine output will be restrained and the reduction in torque will be compensated by the generator. Can do. However, when energy is consumed by friction of the clutch as described in Patent Document 1, since the energy becomes heat, the temperature of the clutch may be increased and the durability thereof may be reduced. In addition, if the amount of power generated by the generator is limited in order to maintain the durability of the clutch, the torque generated by the generator is limited in addition to the limit of the engine output. Torque may be insufficient.

  The present invention has been made paying attention to the above technical problem, and even when charging is restricted, the drive torque can be reduced without causing inconveniences such as a decrease in durability of the power transmission device. An object of the present invention is to provide a control device that can be suitably controlled.

  In order to achieve the above object, the present invention divides the power output from the engine into a drive wheel side and a generator side by a differential mechanism, and drives the electric motor with the electric power generated by the generator to In a control device for a power transmission device that outputs a torque of an electric motor toward the drive wheel and charges at least a part of the electric power generated by the generator to a power storage device, the electric motor is connected via the differential mechanism. The power storage device is arranged at a position deviated from the transmission path for transmitting the power of the engine to the drive wheel, a fluid coupling is disposed between the electric motor and the transmission path, and the electric power generated by the generator is When the charging is restricted, the electric motor is driven by the electric power while the fluid coupling is differentially configured to cause a power loss. It is intended to.

  In addition, when “charging the generated power storage device to the power storage device is restricted”, the chargeable power value is less than a predetermined value due to a large amount of power already charged in the power storage device. This includes cases where charging is restricted for this reason, and even when the chargeable power value is large, the generated power when the generator is controlled to satisfy the required driving force exceeds the chargeable power value. .

  The present invention is configured to control the torque of the electric motor so that a power that cannot be charged in the power storage device out of a power output from the engine is equal to a power consumed by making a differential of the fluid coupling. It may be.

  Further, according to the present invention, when the engine outputs a predetermined power, torque transmitted to the drive wheel via the transmission path and torque transmitted to the transmission path via the fluid coupling The torque of the electric motor may be controlled so that the sum of

  In the present invention, the transmission path includes a power split mechanism that performs a differential action by at least three rotating elements, and among the rotating elements, the engine torque is input to the first rotating element, and the second rotating element is input to the second rotating element. The generator is connected, the third rotating element is an output element, and the torque is transmitted from the electric motor to the driving wheel from the third rotating element via the fluid coupling. It may be.

  According to the present invention, when it is restricted to charge the power storage device with the electric power generated by the generator while the engine is driven, the rotational speed of the electric motor is increased and power is consumed by the fluid coupling. The restrictions on the power generated by the generator and the reaction torque by the generator are relaxed. As a result, the engine torque output via the differential mechanism is sufficiently increased.

  In that case, excessive power consumption can be suppressed by controlling the torque of the electric motor so that the surplus power that cannot be charged by the power storage device is equal to the loss power.

  Further, the fluid coupling is such that the sum of the engine torque transmitted to the drive wheels and the torque of the motor transmitted to the drive wheels via the fluid coupling is maximized when the engine is outputting a predetermined power. Since the differential amount and the output torque of the electric motor are controlled, a sufficient driving torque for traveling can be ensured.

It is a schematic diagram which shows an example of the gear train in the power transmission device (hybrid vehicle) which is a control object of the control device according to the present invention. It is a block diagram for demonstrating the control system of the hybrid vehicle. 4 is a chart collectively showing the engagement and disengagement states of the first clutch, the second clutch, and the brake in each travel mode of the hybrid vehicle, and the functions of each motor / generator. It is an alignment chart which shows the operation state in hybrid mode. It is a flowchart for demonstrating an example of the control currently performed by the control apparatus which concerns on this invention. It is a diagram which shows the relationship between balance of power and torque. It is a figure which shows the model for demonstrating the calculation performed with the control apparatus of the Example of this invention. It is a flowchart for demonstrating an example of the control which calculates | requires the target torque of an engine and a 2nd motor generator. It is a figure which shows the relationship between the torque of a 2nd motor generator, engine power, and direct torque. It is a time chart which shows changes, such as the number of rotations of the 2nd motor generator, the oil pressure of a lockup clutch, etc. when the control device concerning this invention controls when stopping in preparation for the start in hybrid mode.

  FIG. 1 shows an example of a gear train of a power transmission device in a hybrid vehicle controlled by the control device of the present invention. On the same axis as the engine (ENG) 20, an overdrive mechanism 21 and a power are sequentially arranged from the engine 20 side. A dividing mechanism 22 and a first motor / generator (MG1) 23 are arranged. The engine 20 is an internal combustion engine such as a gasoline engine or a diesel engine. The overdrive mechanism 21 is a mechanism for increasing the output rotational speed from the engine rotational speed, and in the example shown in FIG. 1, is constituted by a single pinion type planetary gear mechanism. Therefore, the overdrive mechanism 21 includes a sun gear S21, a ring gear R21 arranged concentrically with the sun gear S21, and a carrier C21 holding the pinion gear meshed with the sun gear S21 and the ring gear R21 so as to be capable of rotating and revolving. It has. An input shaft 24 to which power is transmitted from the engine 20 is connected to the carrier C21. A first clutch C1 that selectively connects the sun gear S21 and the carrier C21 and a brake B1 that selectively fixes the sun gear S21 are provided. Therefore, when the clutch C1 is engaged, the overdrive mechanism 21 is rotated as a whole so as to rotate so as to become a so-called direct connection stage (low), and the speed ratio in the overdrive mechanism 21 is "1". On the other hand, if the brake B1 is engaged to stop the rotation of the sun gear S21, the rotation speed of the ring gear R21 becomes higher than that of the carrier C21, and the so-called overdrive stage (high) where the gear ratio is smaller than "1". It becomes. If the first clutch C1 and the brake B1 are engaged together, the entire overdrive mechanism 21 is fixed and the rotation of the engine 20 is also stopped. Further, if both the first clutch C1 and the brake B1 are released, the sun gear S21 is in a free rotation state, so the overdrive mechanism 21 does not transmit torque.

  The ring gear R21 is an output element and transmits power to the power split mechanism 22. In the example shown in FIG. 1, the power split mechanism 22 is constituted by a single pinion type planetary gear mechanism, and corresponds to the differential mechanism in the embodiment of the present invention. Therefore, power split device 22 includes sun gear S22, ring gear R22 arranged concentrically with sun gear S22, and carrier C22 holding pinion gear meshed with sun gear S22 and ring gear R22 so that they can rotate and revolve. The three rotation elements are provided. A ring gear R21 in the overdrive mechanism 21 is connected to the carrier C22. The output element in the power split mechanism 22 is a ring gear R22, and an output gear 25 is connected to the ring gear R22. A first motor / generator 23 is connected to the sun gear S22, and the sun gear S22 is a reaction force element. The first motor / generator 23 corresponds to the generator in the embodiment of the present invention.

  The sun gear S22 is integrated with the sun gear shaft, and the input shaft 24 passes through the sun gear shaft so as to be rotatable. A second clutch CS that selectively connects the input shaft 24 and the sun gear S22 is provided. As will be described later, the second clutch CS is a clutch for setting the series mode.

  A counter shaft 26 is disposed in parallel with the input shaft 24, and a driven gear 27 and a drive gear 28 are provided on the counter shaft 26 so as to rotate together. The output gear 25 is meshed with the driven gear 27. Further, the drive gear 28 meshes with a ring gear 30 in a differential gear 29 that is a final reduction gear. The driving force is transmitted from the differential gear 29 to the left and right driving wheels 31. The gear train composed of the driven gear 27 and the drive gear 28 constitutes a speed reduction mechanism. The path L for transmitting power from the output gear 25 to the drive wheel 31 via the counter shaft 26 and the differential gear 29 corresponds to the transmission path in the embodiment of the present invention. In FIG. 1, for convenience of drawing, the drive gear 28 and the differential gear 29 are shown on the right side in FIG.

  A second motor / generator 32 corresponding to the electric motor in the embodiment of the present invention is arranged in parallel with the input shaft 24 and the counter shaft 26. Further, a fluid coupling 33 is disposed on the same axis as the second motor / generator 32. The fluid coupling 33 includes a lockup clutch CL. Therefore, the second motor / generator 32 and the fluid coupling 33 are provided at positions outside the transmission path described above. In the fluid coupling 33, a pump impeller 35 that is a driving side member and a turbine runner 36 that is a driven side member are arranged to face each other, and a spiral flow of fluid (or oil) generated by the pump impeller 35 is transmitted to the turbine runner 36. By supplying, torque is transmitted between the pump impeller 35 and the turbine runner 36. The lockup clutch CL is disposed in parallel with the pump impeller 35 and the turbine runner 36. The pump impeller 35 is connected to the second motor / generator 32. A turbine shaft 37 integral with the turbine runner 36 extends through the center of the second motor / generator 32 toward the driven gear 27. Then, another drive gear 38 meshing with the driven gear 27 is attached to the turbine shaft 37.

  The lock-up clutch CL is a clutch that mechanically connects the pump impeller 35 or a member integral therewith and the turbine runner 36 or a member integral therewith to transmit torque, and is controlled by hydraulic pressure and has a transmission torque capacity. It consists of a continuously changing clutch. A damper 39 is provided in series with the lockup clutch CL. The fluid coupling 33 and the lockup clutch CL may be a conventionally known torque converter with a lockup clutch.

  The power (power) output from the engine 20 is divided into the first motor / generator 23 side and the output gear 25 side by the power split mechanism 22 described above. In this case, the first motor / generator 23 functions as a generator to give a reaction torque to the sun gear S22. As a result, the engine torque is amplified by the power split mechanism 22 and output from the output gear 25. This engine torque may be referred to as direct torque, and the direct torque is transmitted to the drive wheels 31 via the transmission path L. In other words, since the torque output from the engine 20 is not applied to the fluid coupling 33, the fluid coupling 33 can be made small and small in capacity.

  The electric power generated by the first motor / generator 23 is supplied to the second motor / generator 32, and the second motor / generator 32 functions as a motor, and the output torque is the torque output from the output gear 25 in the driven gear 27. Added to. Accordingly, the motor / generators 23 and 32 are electrically connected via the power supply unit 42 including the inverter 40 and the power storage device 41. In addition, these motor generators 23 and 32 are comprised by the three-phase synchronous motor as an example.

  A control system for the hybrid vehicle is shown in a block diagram in FIG. A motor / generator electronic control unit (MG-ECU) 43 for controlling the motor / generators 23 and 32 and an engine electronic control unit (ENG-ECU) 44 for controlling the engine 20 are provided. These electronic control units 43 and 44 are mainly composed of a microcomputer, and are configured to perform calculations based on various input signals or data and output the calculation results as control command signals. . The MG-ECU 43 is mainly configured to control respective currents (MG1 current, MG2 current) of the first motor / generator 23 and the second motor / generator 32. The ENG-ECU 44 is mainly configured to output an electronic throttle opening signal for instructing the opening of an electronic throttle valve (not shown) to the engine 20 and an ignition signal for instructing ignition and its timing. Has been.

  A command signal is output to these electronic control devices 43 and 44, and the electronic control for hybrid which controls the engagement and disengagement of each clutch C1, CS, CL and brake B1 and control of the transmission torque capacity is also performed. A device (HV-ECU) 45 is provided. The HV-ECU 45 is configured mainly with a microcomputer, similar to the electronic control units 43 and 44 described above, and performs calculations based on various types of input signals or data, and outputs the calculation results as control command signals. Is configured to output as Examples of the input data include vehicle speed, accelerator opening, detection data by the rotation speed sensor of the first motor / generator (MG1), detection data by the rotation speed sensor of the second motor / generator (MG2), output shaft ( For example, detection data by the rotation speed sensor of the counter shaft 26), a remaining charge (SOC), a signal from an offload switch, and the like. As an example of the command signal to be output, the torque command of the first motor / generator (MG1) and the torque command of the second motor / generator (MG2) are output to the MG-ECU 43, and the engine torque command is transmitted to the ENG- It is output to the ECU 44. Further, the control hydraulic pressures PbC1, PbCS, PbCL, PbB1 of the clutches C1, CS, CL and the brake B1 are output from the HV-ECU 45. Each of the ECUs 43, 44, 45 constitutes a controller.

  Various driving modes are set by causing each of the motor generators 23 and 32 to function as a motor or a generator and controlling the clutches C1 and CS and the brake B1 to be engaged or disengaged. FIG. 3 summarizes the travel modes. The hybrid mode (HV) is a mode in which a driving force is generated by the engine 20 and the motor / generators 23 and 32, and the parallel mode and the series mode can be selected. The advance in the parallel mode can be performed with the above-described overdrive mechanism 21 set to the overdrive stage (high) or the direct drive stage (low). The overdrive stage is set by engaging only the brake B1, and in this case, the first motor / generator 23 is caused to function as a generator (G) to control the rotational speed of the engine 20 to a fuel efficient rotational speed. The electric power generated by the first motor / generator 23 is supplied to the second motor / generator 32, and the second motor / generator 32 functions as a motor (M). On the other hand, the direct connection stage is set by engaging only the first clutch C1, and the functions of the motor generators 23 and 32 in that case are the same as in the case of traveling in the overdrive stage.

  FIG. 4 shows a collinear diagram of the planetary gear mechanism constituting the overdrive mechanism 21 and the planetary gear mechanism constituting the power split mechanism 22 when traveling in the hybrid mode. The left side of FIG. 4 is an alignment chart for the overdrive mechanism 21, and the right side is an alignment chart for the power split mechanism 22. At the time of forward movement, the sun gear S21 is fixed by the brake B1 and the carrier C21 is rotated by the engine 20, so that the ring gear R21 rotates at a speed higher than the engine speed. That is, the overdrive stage has a gear ratio smaller than “1”. In the power split mechanism 22, the carrier C22 rotates together with the ring gear R22 in the overdrive mechanism 21, and the torque becomes a torque in the positive direction (the rotation direction of the engine 20). In this state, the first motor / generator 23 functions as a generator, the torque in the negative direction (the direction in which the rotation is stopped) acts on the sun gear S22, and the accompanying torque in the positive direction acts on the ring gear R22. That is, the power of the engine 20 is divided into the sun gear S22 side and the ring gear R22 side. Since the electric power generated by the first motor / generator 23 is supplied to the second motor / generator 32 and the second motor / generator 32 functions as a motor, the torque is added to the torque output from the ring gear R22. Is output toward the drive wheel 31. The operation state when the direct drive stage is set by the overdrive mechanism 21 is shown by a broken line in FIG. The reverse travel is performed by rotating the first motor / generator 23 with the power output from the engine 20 to generate electric power and causing the second motor / generator 32 to function as a motor in the negative rotation direction with the electric power.

  The series mode is a mode in which the first motor / generator 23 is driven by the engine 20 as a generator and the second motor / generator 32 is driven by the electric power as a motor. Therefore, by engaging only the second clutch CS, the power of the engine 20 is transmitted to the first motor / generator 23, and the first motor / generator 23 functions as a generator (G). The second motor / generator 32 is supplied with electric power generated by the first motor / generator 23 and functions as a motor (M). The second motor / generator 32 rotates forward in the forward direction and travels backward in the negative direction.

  The EV mode is a mode in which the power of the power storage device is used without using the power of the engine 20, and thus the vehicle runs as an electric car (EV). Since the second motor / generator 32 is connected to the driving wheel 37 via the fluid coupling 33 or the lock-up clutch CL, in the EV mode, the second motor / generator 32 mainly operates as a driving force source, and the driving force or the braking force is controlled. When the power is insufficient, the first motor / generator 23 is used together. That is, a single drive mode using only the second motor / generator 32 and a double drive mode using both the motor / generators 23 and 32 are possible.

  In the single drive mode, since only the second motor / generator 32 operates as a driving force source, the clutches C1, CS and the brake B1 are released, and the first motor / generator 23 performs power running and regeneration without any particular control. Do neither. The second motor / generator 32 functions as a motor (M) when driven, and functions as a generator (G) during braking. When the braking force accompanying regeneration is insufficient, at least one of the first clutch C1 and the brake B1 is engaged. Moreover, each motor generator 23,32 functions as a generator (G), and the negative torque accompanying power generation acts as a braking force.

  Both drive modes are travel modes in which the first clutch C1 and the brake B1 are engaged, and the motor generators 23 and 32 both operate as motors (M). The overdrive mechanism 21 is engaged as a whole with the first clutch C1, and the brake B1 is engaged in this state, whereby the overdrive mechanism 21 is stopped from rotating as a whole. Therefore, the carrier C22 of the power split mechanism 22 connected to the ring gear R21 is fixed, and in this state, the first motor / generator 23 operates as a motor in the negative rotation direction. Therefore, the torque generated by the first motor / generator 23 is output from the ring gear R22 as torque in the forward rotation direction. The second motor / generator 32 operates as a motor in the forward rotation direction. Therefore, the torque of the second motor / generator 32 is added to the torque output from the output gear 25. During reverse travel, the direction of torque of each motor / generator 23, 32 is opposite to that during forward travel.

  When traveling in the hybrid mode, the first motor / generator 23 functions as a generator to apply a reaction torque to the sun gear S22, and the torque input from the engine 20 to the carrier C22 constitutes the power split mechanism 22. Amplified according to the gear ratio of the planetary gear mechanism (ratio of the number of teeth of the ring gear R22 and the number of teeth of the sun gear S22) and output from the output gear 25 toward the drive wheels 31. Therefore, when the reaction torque generated by the first motor / generator 23 is small, the engine torque output from the output gear 25 is small. Since the first motor / generator 23 generates reaction force torque by generating electric power, the reaction force torque is reduced when power generation is limited. An example in which power generation is limited is a case where the amount of charge (SOC) of the power storage device 41 is sufficiently large and a so-called full charge or a state of charge close to this reaches a predetermined upper limit value. In order to ensure the driving torque in such a state, the control device according to the present invention is configured to execute the control described below.

  FIG. 5 is a flowchart for explaining the control example. This control routine is repeatedly executed every predetermined short time by the HV-ECU 45 when the engine 20 is outputting power. After the start of the routine, it is first determined whether or not charging to the power storage device 41 is restricted (step S1). This determination may be made, for example, by comparing the SOC input to the HV-ECU 45 with a reference value stored in advance. If the power storage device 41 is so-called fully charged or is in a state close to being fully charged, affirmative determination is made in step S1, the target torque Tm_tgt of the second motor / generator 32, the engine 20 Target slip Te_tgt and the slip amount of the lockup clutch CL (that is, the differential amount of the fluid coupling 33) are calculated (step S2). An example of the calculation will be described below.

  FIG. 6 shows the relationship between the balance of power and torque when starting from a state where the engine 20 is driven and stopped. The rotational speed Ne and the power Pe_real of the engine 20 are predetermined values, which are larger than the required power Pe_dem. The difference in power is charged as battery power Pbat when the charge amount of the power storage device 41 has a margin. This battery power Pbat is the power Win charged in the power storage device 41. On the other hand, the torque output from the engine 20 is increased / decreased by the overdrive mechanism 21 and the power split mechanism 22 and output toward the drive wheels 31, and the torque is the direct torque Te ′. Further, by supplying the electric power generated by the first motor / generator 23 to the second motor / generator 32, the second motor / generator 32 outputs the torque Tm. Therefore, the engine 20 and the second motor / generator 32 The output torque Tout is a torque (Tm + Te ′) obtained by adding the direct torque Te ′ and the torque Tm of the second motor / generator 32. In the power train having the configuration shown in FIG. 1, the torque Tm of the second motor / generator 32 is the torque Tturbin of the turbine runner 36.

  As the engine speed Ne increases as the vehicle speed V increases, the difference between the actual power Pe_real and the required power Pe_dem, that is, the surplus power gradually decreases and finally becomes zero. If the power storage device 41 can be charged in the process, the desired output torque Tout can be obtained. The required power Pe_dem is obtained in the same manner as conventionally known driving force control based on the required driving amount such as the accelerator opening, the vehicle speed, a map prepared in advance, and the like. On the other hand, when there is a charge restriction, the surplus power is restricted, so that the direct torque Te ′ by the engine 20 is restricted and the output torque Tout becomes insufficient. Therefore, the control device in the embodiment of the present invention secures the output torque Tout by consuming the power that cannot be received (charged) by the power storage device 41 as a loss.

FIG. 7 shows a model for explaining the calculation executed by the control device of the embodiment of the present invention. The power Pe output from the engine 20 is the product (Ne × Te) of the rotational speed Ne and the torque Te. The direct torque Te ′ based on the torque is transmitted to the counter shaft 26 and the drive wheels 31 via the driven gear 27. On the other hand, the first motor / generator 23 is driven by the engine 20 to generate electric power, and the electric power is supplied to the power storage device 41 and the second motor / generator 32. The second motor / generator 32 operates as a motor with the supplied electric power and outputs a torque Tm. In a state where the lock-up clutch CL is released, there is a difference between the rotational speed Nfin of the pump impeller 35 and the rotational speed Nfout of the turbine runner 36. The torque Tpump of the pump impeller 35 is a product (τ × Nfin ² ) of the capacity coefficient τ of the fluid coupling 33 and the square of the rotational speed Nfin, and the torque of the turbine runner 36 is Tturbin. It is a product (τ × Nfout ² ) with the square of Nfout. The torque of the turbine runner 36 is transmitted from the drive gear 38 to the driven gear 27 or the counter shaft 26 and is added to the direct torque Te ′ to become an output torque Nout. The output rotation speed is represented by Nout. Then, when the pump impeller 35 and the turbine runner 36 rotate relative to each other, a power loss accompanying oil shearing or stirring occurs, and heat corresponding to the loss power Ploss is generated. That is, so-called surplus power that cannot be received by the power storage device 41 is consumed as loss power Ploss.

  In this case, the loss power Ploss increases as the so-called slippage or differential rotational speed at the fluid coupling 33 increases. On the other hand, the torque output from the fluid coupling 33, that is, the turbine torque Tturbin decreases, and the output torque Tout decreases. It becomes. Therefore, the slip amount of the lockup clutch CL, the torque Te of the engine 20 and the torque Tm of the second motor / generator 32 are controlled so that the surplus power that cannot be received by the power storage device 41 and the power consumed by the fluid coupling 33 become equal. Is done. An example of the control is shown in the flowchart of FIG.

The routine shown in FIG. 8 is a subroutine executed in step S2 in FIG. 1 described above. First, the torque Tm of the second motor / generator 32 is obtained (step S21). The torque Tm of the second motor / generator 32 is gradually increased from zero, the initial value Tm (0) is set to zero, and a predetermined increase ΔTm for each cycle in which the routine of FIG. Calculated by adding to Tm (i).
Tm (i + 1) = Tm (i) + ΔTm

On the other hand, the direct torque Te ′ is calculated (step S22). The direct torque Te ′ is obtained by subtracting the torque Tm from the second motor / generator 32 from the requested output torque Tout_dem. The required output torque Tout_dem is obtained from the required power based on the required drive amount such as the accelerator opening and the vehicle speed, and the required power and the vehicle speed.
Te ′ (i + 1) = Tout_dem−Tm (i + 1)

Next, the engine power Pe (i + 1) is calculated from the engine torque Te (i + 1) and the actual engine speed Ne_real (step S23). Here, the engine torque Te (i + 1) is obtained based on the direct torque Te ′ (i + 1) and the gear ratio in the power split mechanism 22 and the transmission path L. Further, the actual engine speed Ne_real can be obtained based on the vehicle speed V, the accelerator opening, a map prepared in advance, and the like.
Pe (i + 1) = Te (i + 1) × Ne_real

Of the engine power Pe (i + 1), the surplus power excluding the power (amount of power) Win that can be charged in the power storage device 41 is the required loss power Ploss. Calculated (step S24).
Ploss_dem (i + 1) = Pe (i + 1) + Win
The power Win that can be charged is a negative value in the above formula.

It is determined whether or not the actual loss power Ploss_real (i + 1) is substantially equal to the required loss power Ploss_dem (step S25). This determination may be a determination as to whether or not the difference between the actual loss power Ploss_real (i + 1) and the required loss power Ploss_dem is smaller than a predetermined reference value. The actual loss power Ploss_real (i + 1) can be obtained by the following calculation.
Ploss = τNfin ²・ Nfin−τNfin ²・ Nfout
= ΤNfin ² (Nfin-e · Nin)
= ΤNm ³ (1-e)
Nfin = Nm (the rotational speed of the second motor / generator 32), and e is the speed ratio in the fluid coupling 33,
e = Nfout / Nfin
It is. Accordingly, the rotational speed Nfout of the turbine runner 36 is obtained from the vehicle speed, and the torque Tm of the second motor / generator 32 is the value determined in step S21 in FIG. 8, so the actual loss power Ploss is obtained.

  If the difference between the required value and the actual value for the loss power Ploss is still large and thus a negative determination is made in step S25, the count value i is incremented (i + 1) (step S26). Then, it returns to step S21. On the other hand, if a positive determination is made in step S25, the required loss power Ploss_dem may be substantially satisfied by the torque Tm of the second motor / generator 32 and the speed ratio e of the fluid coupling 33 at that time. It will be possible. Therefore, the torque Tm (i) of the second motor / generator 32 at that time is set to the target torque Tm_tgt, and the engine torque Te (i) at that time is set to the target engine torque Te_tgt (step S27).

  In the routine shown in FIG. 5, the second motor / generator 32 and the engine 20 are controlled so as to achieve the target torques determined as described above, and the lock-up clutch is controlled so as to achieve the speed ratio e. The slip amount of CL is controlled (step S23). In other words, the hydraulic pressure of the lock-up clutch CL may be feedback-controlled so that the speed ratio that achieves the required loss power is obtained. Note that, in the routine shown in FIG. 1, if a negative determination is made in step S1 because charging is not restricted, the lockup clutch CL is controlled to be engaged (step S4).

  As shown in step S22 above, if the torque Tm of the second motor / generator 32 is increased and the loss power Ploss is large, the direct torque Te 'is decreased, the output torque Tout is insufficient, and the energy is lost. Will increase. Conversely, if the torque Tm of the second motor / generator 32 is reduced and the loss power Ploss is reduced, it is necessary to reduce the engine power to reduce the surplus power, and the output torque Tout is reduced accordingly. On the other hand, in the control according to the embodiment of the present invention described above, the entire amount of surplus power that cannot be charged in the power storage device 41 is consumed as loss power by the fluid coupling 33. When the battery power Win of the power storage device 41 is zero, the fluid coupling 33 consumes all of the engine power that is used for power generation (power other than so-called direct power for traveling).

  This relationship is shown in FIG. The direct torque Te ′ decreases as the torque Tm of the second motor / generator 32 increases. Similarly, the engine power Pe corresponding to the direct torque Te ′ increases as the torque Tm of the second motor / generator 32 increases. descend. On the other hand, the loss power Ploss increases as the torque Tm of the second motor / generator 32 increases. If the power storage device 41 can be charged, the charging power (battery power) Win is added to the loss power Ploss, and the value increases as the second motor / generator 32 increases.

  In the control example shown in FIG. 8 described above, since the torque Tm of the second motor / generator 32 is gradually increased, the loss power Ploss (or the power obtained by adding the battery power Win) is initially small. Therefore, the surplus power that cannot be received by the power storage device 41 has a large value as indicated by the alternate long and short dash line. As the torque Tm of the second motor / generator 32 increases, the loss power Ploss (or the power obtained by adding the battery power Win) increases and the surplus power gradually decreases. As a result, the two finally match. This is a state in which a positive determination is made in step S25 in the control example shown in FIG. Therefore, the torque at the operating point (the point indicated by a circle in FIG. 9) where the loss power Ploss (or the power obtained by adding the battery power Win to this) and the surplus power coincides with the target torque Tm_tgt of the second motor / generator 32. It is said. At this operating point, the sum of the direct torque Te ′ and the torque Tm of the second motor / generator 32 is maximized.

  In the above embodiment, in order to simplify the explanation, the energy balance is calculated from the energy generated by the first motor / generator 23 and the energy lost (consumed) by the fluid coupling 33. In the present invention, the present invention is not limited to this. Actually, the electric power generated by the first motor / generator 23 is not only consumed by the fluid coupling 33 but also the first motor / generator 23 operates. And is consumed by a loss in an electric circuit such as an inverter for controlling the motor generators 23 and 32. Therefore, in the present invention, in consideration of the energy consumption, the fluid coupling is finally used. At 33, the energy to be consumed may be calculated.

  The control example shown in FIG. 8 is an example in which the point D is obtained by gradually increasing the torque of the second motor / generator 32. In the control device according to the embodiment of the present invention, On the other hand, the torque Tm of the second motor / generator 32 may be initially sufficiently increased, and the torque at the point D may be obtained by gradually decreasing the torque Tm from that state.

  Changes in the engine speed and torque, the rotational speed and torque of each motor / generator 23, 32, the hydraulic pressure of the lockup clutch CL, etc. when the control shown in FIG. 1 is performed are shown as a time chart in FIG. is there. In a state where the engine 20 rotates at a predetermined rotational speed such as an idle rotational speed and the vehicle is stopped, the first motor / generator 23 functions as a generator. The second motor / generator 32 is stopped because the vehicle is stopped, and its torque is set to a predetermined small torque. Therefore, a part of the electric power generated by the first motor / generator 23 is consumed by the second motor / generator 32, and most of the electric power is charged in the power storage device 41. Therefore, the SOC gradually increases. When the SOC reaches a predetermined threshold value set in advance as a value smaller than the value indicating the fully charged state (at time t1), the torque of the second motor / generator 32 is increased, and the power consumption gradually increases. Furthermore, since the vehicle is stopped, the overdrive mechanism 21 is in the direct coupling stage (low). That is, the hydraulic pressure of the first clutch C1 is controlled to a predetermined pressure and the first clutch C1 is engaged, and the hydraulic pressure of the brake B1 is controlled to zero and the brake B1 is released.

  During this time, the power storage device 41 is being charged and the SOC is increasing. When the SOC reaches a predetermined value α close to full charge (at time t2), the slip control of the fluid coupling 33 is started. The Specifically, the hydraulic pressure of the lockup clutch CL is gradually lowered, the lockup clutch CL starts to slip, and the second motor / generator 32 starts to rotate. The torque of the second motor / generator 32 is maintained at the current torque. Further, since the amount of energy consumption increases due to the rotation of the second motor / generator 32, the number of rotations of the first motor / generator 23 is increased, and the torque (negative torque in the direction of stopping the rotation) increases. Be made. Further, the rotational speed and torque (ie, power) of the engine 20 are controlled so as to satisfy the required drive amount.

  Then, when the SOC further approaches the fully charged state (for example, the difference between the current SOC value and the fully charged value falls below a predetermined value) (at time t3), the hydraulic pressure of the lockup clutch CL is set to a predetermined minimum pressure. Thus, the slip amount of the fluid coupling 33 is set to a predetermined maximum value. Further, the rotational speed and torque of the engine 20 and the rotational speed and torque of the first motor / generator 23 are maintained at the rotational speed and torque at that time. Since the SOC continues to increase at that time, the second motor / generator 32 increases the torque while maintaining the rotation speed, and consumes the electric power generated by the first motor / generator 23. When all of the electric power generated by the first motor / generator 23 is consumed by the second motor / generator 32 (at time t4), the torque of the second motor / generator 32 is maintained at the torque at that time. .

  According to the control apparatus of the embodiment of the present invention, by performing the above-described control, it is possible to generate power by the first motor / generator 23 and to generate a reaction force torque accompanying the power generation. Can be large. That is, the electric power generated by the first motor / generator 23 is consumed by causing the fluid coupling 33 to cause a differential rotation and rotating the second motor / generator 32. Therefore, the torque output by the second motor / generator 32 is consumed. It can be used as drive torque. In particular, since the control is performed so that the sum of the direct torque Te ′ and the torque Tm of the second motor / generator 32 is maximized, a necessary and sufficient driving force corresponding to the required driving amount can be obtained. In addition, since the second motor / generator 32 and the fluid coupling 33 are provided at positions away from the transmission path for transmitting the direct torque Te ′ to the drive wheels 31, the direct torque Tor ′ from the engine 20 is applied to the fluid coupling 33. Therefore, the fluid coupling 33 can be made small with a small capacity. Furthermore, even if surplus energy is consumed as loss energy Ploss and heat is generated, heat is generated by the oil in the fluid coupling 33 itself, and the oil is circulated with an oil cooler (not shown) to transfer the heat to the outside. Therefore, a decrease in durability due to heat can be avoided or suppressed.

  The hybrid vehicle targeted by the present invention is basically provided between an engine, a generator, a power split mechanism in which the engine and the generator are connected, an electric motor, and the electric motor and drive wheels. The vehicle is not limited to the hybrid vehicle including the gear train having the configuration shown in FIG. For example, the above-described overdrive mechanism may not be provided.

  DESCRIPTION OF SYMBOLS 1 ... Electric vehicle, 2 ... Driving force source, 3 ... Electric motor, 4 ... Power storage device, 7 ... Drive wheel, 8 ... Transmission path, 9 ... Power transmission mechanism, 11 ... Fluid coupling, 12 ... Engagement mechanism, 13 ... Drive Side member, 14 ... Driven side member, 15 ... Electronic control unit (ECU), 20 ... Engine, 21 ... Overdrive mechanism, 22 ... Power split mechanism, 23 ... First motor / generator (MG1), 31 ... Drive wheel, 32 ... Second motor / generator, 33 ... Fluid coupling, CL ... Lock-up clutch, 35 ... Pump impeller, 36 ... Turbine runner, 40 ... Inverter, 41 ... Power storage device, 42 ... Power supply unit, 43 ... Electronics for motor / generator Control device (MG-ECU), 44 ... Engine electronic control device (ENG-ECU), 45 ... Hybrid electronic control device (HV-) CU), L ... transmission path.

Claims (4)

The power output from the engine is divided into a drive wheel side and a generator side by a differential mechanism, and the motor is driven by the electric power generated by the generator to output the torque of the motor toward the drive wheel, And in the control device of the power transmission device capable of charging the power storage device at least a part of the electric power generated by the generator,
The electric motor is disposed at a position deviated from a transmission path that transmits the power of the engine to the drive wheels via the differential mechanism,
A fluid coupling is disposed between the electric motor and the transmission path,
When it is restricted to charge the power storage device with the power generated by the generator, it is configured to cause a power loss by driving the electric motor with the power while making the fluid coupling differential. A control device for a power transmission device. In the control apparatus of the power transmission device according to claim 1,
It is configured to control the torque of the electric motor so that the power that cannot be charged in the power storage device out of the power output from the engine and the power consumed by the differential of the fluid coupling are equal. A control device for a power transmission device. In the control apparatus of the power transmission device according to claim 1,
When the engine outputs a predetermined power, the sum of the torque transmitted to the drive wheel via the transmission path and the torque transmitted to the transmission path via the fluid coupling is maximum. It is comprised so that the torque of the said motor may be controlled, The control apparatus of the power transmission device characterized by the above-mentioned. In the control apparatus of the power transmission device according to any one of claims 1 to 3,
The transmission path includes a power split mechanism that performs differential action by at least three rotating elements,
Among the rotating elements, torque of the engine is input to the first rotating element, the generator is connected to the second rotating element, and the third rotating element is an output element,
A control device for a power transmission device, wherein the torque transmitted from the third rotating element to the drive wheel is added from the motor via the fluid coupling.

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